EP3734673A1

EP3734673A1 - Light source system and lighting device

Info

Publication number: EP3734673A1
Application number: EP18895195.8A
Authority: EP
Inventors: Meng Zhou; Yi Li
Original assignee: YLX Inc
Current assignee: YLX Inc
Priority date: 2017-12-28
Filing date: 2018-05-25
Publication date: 2020-11-04
Also published as: WO2019128079A1; US20200400299A1; EP3734673A4; US11098886B2

Abstract

The present disclosure provides a light source system and a lighting device including the same. The light source system includes at least one laser configured to emit excitation light, a substrate, a reflective layer, a wavelength conversion layer, and a light guiding element. The substrate is made of material with a high thermal conductivity and provided with a notch. The laser is received in a sidewall of the notch. The reflective layer covers walls of the notch and is configured to reflect the excitation light. The wavelength conversion layer is provided on a part of a surface of the reflective layer and configured to perform wavelength conversion on the excitation light to obtain excited light. The light guiding element covers an opening of the notch and configured to guide the excitation light and the excited light, to obtain light source light to be emitted by the light source system. The light source system solves a heat dissipation problem of the laser and the wavelength conversion layer.

Description

TECHNICAL FIELD

The present disclosure relates to the technical field of light sources, and in particular, to a light source system and a lighting device.

BACKGROUND

This section is intended to provide a background or context for specific embodiments of the present disclosure recited in the claims. The description here is not admitted to be prior art just because it is included in this section.
At present, a solid-state light source used in the lighting field uses a blue laser and phosphors to output white light. The blue laser can operate at high drive power densities and produce relatively high luminous flux. A light source using the blue laser can have brightness which is dozens of times higher than that of an LED. For applications with strict restrictions in volume and etendue, the blue laser has inherent advantages as light sources.
At present, the solid-state light sources with the blue laser still have certain technical problems, such as heat dissipation problems of a blue laser chip and a wavelength conversion layer.

SUMMARY

The present disclosure provides a light source system and a lighting device which can solve the heat dissipation problems of an internal laser and a wavelength conversion layer.
A light source system includes:

at least one laser configured to emit excitation light;
a substrate made of material with a high thermal conductivity and provided with a notch, where the at least one laser is received in at least one sidewall of the notch;
a reflective layer covering a wall of the notch and configured to reflect the excitation light;
a wavelength conversion layer provided on a part of a surface of the reflective layer and configured to perform wavelength conversion on the excitation light to obtain excited light; and
a light guiding element covering an opening of the notch and configured to guide the excitation light and the excited light, to obtain light source light to be emitted by the light source system.

A lighting device includes the above light source system.
In the light source system and the lighting device including the light source system provided by the present disclosure, the substrate in the light source system is made of material with a high thermal conductivity, the laser is received in the substrate, and heat of the wavelength conversion layer is transferred to the substrate through the reflective layer, thereby solving the heat dissipation problems of the laser and the wavelength conversion layer in the light source system. In addition, since the laser and the wavelength conversion layer are located in the same notch, the light source system and the lighting device each have a small volume and each have a simple and compact structure.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a three-dimensional schematic diagram of a light source system provided by a first embodiment of the present disclosure.
FIG. 2 is a cross-sectional view of a light source system shown in FIG. 1 taken along a line II-II.
FIG. 3 is a top view of a light source system shown in FIG. 2.
FIG. 4 is a cross-sectional view of a light source system provided by a second embodiment of the present disclosure.
FIG. 5 is a top view of the light source system shown in FIG. 4.
FIG. 6 is a schematic diagram of spots on a wavelength conversion layer shown in FIG. 4.
FIG. 7 is a cross-sectional view of a light source system provided by a third embodiment of the present disclosure.

Symbol description of main components

Light source system	100, 200, 300
Substrate	110, 210
Notch	111,211
Sidewall	111a, 211a
Bottom wall	111b, 211b
Light guiding element	120, 320
Laser	130, 230, 330
Beam deflecting device	140
Wavelength conversion layer	150, 250, 350
Reflective layer	160, 360

The following specific embodiments will further illustrate the present disclosure with reference to the above drawings.

DESCRIPTION OF EMBODIMENTS

Referring to FIG. 1 to FIG. 3, FIG. 1 is a three-dimensional schematic diagram of a light source system 100 provided by a first embodiment of the present disclosure, FIG. 2 is a cross-sectional view of the light source system 100 shown in FIG. 1 taken along a line II-II, and FIG. 3 is a top view of the light source system shown 100 shown in FIG. 2. The light source system 100 provided by the embodiment of the present disclosure includes a substrate 110, a light guiding element 120, a laser 130, a beam deflecting device 140, a wavelength conversion layer 150, and a reflective layer 160.
The light source system 100 in this embodiment includes at least one laser 130 configured to emit excitation light. The substrate 110 is made of material with a high thermal conductivity, and the material with a high thermal conductivity can be aluminum nitride, silicon nitride, silicon carbide, boron nitride, or metal such as copper or aluminum. The substrate 110 is provided with a notch 111, and the laser 130 is received in a sidewall of the notch 111, thereby solving a heat dissipation problem of the laser 130. In addition, the laser 130 and the wavelength conversion layer 150 are located in a same notch 111, and the light source system 100 and a lighting device to which the light source system 100 is applied have a small volume and a simple and compact structure.
The beam deflecting device 140 and the laser 130 are provided in one-to-one correspondence, and the beam deflecting device 140 is configured to guide the excitation light emitted by a laser 130 corresponding the beam deflecting device 140 to be irradiated to the wavelength conversion layer 150. The beam deflecting device 140 can be a prism, an aspheric lens, a free arc-shaped surface, a reflective mirror, and so on.
The reflective layer 160 can be a diffuse reflective layer or a metal reflective layer, covers a wall of the notch 111 and is configured to reflect light, to improve a light emission efficiency of the light source system 100.
The wavelength conversion layer 150 is provided on a part of a surface of the reflective layer 160 and is configured to perform wavelength conversion on the excitation light to obtain excited light. The wavelength conversion layer 150 transfers heat to the substrate 110 via the reflective layer 160 and dissipates the heat through the substrate 110, thereby solving the heat dissipation problem of the wavelength conversion layer 150.
The light guiding element 120 covers an opening of the notch 111 and is configured to reflect the excitation light and transmit the excited light, and the excited light is emitted from the light guiding element 120 to obtain light source light to be emitted by the light source system 100.
The substrate 110 of the light source system 100 is made of material with a high thermal conductivity, and the laser 130 is received in the wall of the substrate 110. The heat generated by the wavelength conversion layer 150 is transferred to the substrate 110 via the reflective layer 160, thereby solving the heat dissipation problems of the laser 130 and the wavelength conversion layer 150 of the light source system.
In addition, the light source system 100 adopts the laser 130, and the laser 130 and the wavelength conversion layer 150 are received in the notch 111 of the same substrate 110, so that the light source system 100 not only has high light emission brightness, but also has a small volume. The light source system 100 can also be applied to a lighting equipment, and the lighting device provided by the embodiment of the present disclosure can be applied in the fields of automobile lamp devices, stage lights, and laser headlights.
In the first embodiment, the light source system 100 includes four identical lasers 130. The laser 130 can be a blue laser configured to emit blue excitation light. It can be understood that the laser 130 is not limited to the blue laser, and the laser 130 can also be an ultraviolet laser, a red laser, a green laser, or the like. It can be understood that the light source system 100 can include one or two blue lasers or a blue laser array, and the specific number of the lasers 130 of the light source system 100can be selected according to actual needs.
The notch 111 has a shape of a frustum, and the wall of the notch 111 includes four sidewalls 111a and one bottom wall 111b. The laser 130 is exposed at a surface of the substrate 110, and any two lasers 130 are received in different sidewalls 111a of the notch 111. Each beam deflecting device 140 is disposed between the laser 130 corresponding to the beam deflecting device 140 and the light guiding element 120.
It can be understood that, in an embodiment, the light source system 100 includes less than four lasers 130, for example, three lasers 130. Each of any three sidewalls 111a of the notch 111 can be provided with a laser 130. Alternatively, two of the three lasers 130 are disposed on one sidewall 111a and the remaining one laser 130 is disposed on another sidewall 111a. Alternatively, the three lasers 130 are all disposed on any one sidewall 111a if heat dissipation conditions allow. Due to a reflective effect of the reflective layer 160 and filtering characteristics of the light guiding element 120, the excitation light can excite the wavelength conversion layer 150 to generate the excited light, and the excited light is emitted from the light source system 100 to obtain the light source light.
The wavelength conversion layer 150 is provided with yellow phosphors and configured to generate yellow excited light. The yellow excited light is emitted from the light guiding element 120 to obtain yellow light source light.
The wavelength conversion layer 150 is provided on the reflective layer 160 at the bottom wall 111b. The yellow excited light emitted by the wavelength conversion layer 150 and unconverted blue excitation light are directly incident to the light guiding element 120. Under the reflection of the light guiding element 120 and the reflective layer 160, the unconverted part of the excitation light can excite the wavelength conversion layer 150 multiple times until it is converted into excited light and emitted through the light guiding element 120. It can be understood that the wavelength conversion layer 150 can be disposed on the reflective layer 160 at any position of the sidewall 111a, or any positions provided on multiple walls or a partial region of any wall of the notch 111. In addition, the wavelength conversion layer 150 can be configured to generate excited light of other colors under the excitation of the excitation light, such as red and green excited light. That is, the wavelength conversion layer 150 is provided with a red fluorescent material and a green fluorescent material in sections, so that optical power of the generated red excited light and that of the green excited light can reach a preset ratio. It can be understood that, in other embodiments, the wavelength conversion layer 150 can also be provided with yellow and green fluorescent materials, or yellow and red fluorescent materials, or yellow, red, and green fluorescent materials, and it is not limited to this.
In addition, the wavelength conversion layer 150 has a rough surface, to improve the light emission efficiency of the wavelength conversion layer 150 and reduce reflection loss when the excitation light glides at a large angle.
The reflective layer 160 is disposed on the wall, that is, the reflective layer 160 covers four sidewalls 111a and one bottom wall 111b, so as to reflect the light therein from various directions in the light source system 100, thereby increasing the number of the light reflection and improving a conversion efficiency of the excitation light. In addition, the light in the notch 111 can only be emitted from the light guiding element 120, which ensures the light emission efficiency of the light source system 100.
In this embodiment, the light guiding element 120 is configured to reflect the excitation light and transmit the excited light, and the light guiding element 120 can be a beam-splitting filter plated with a blue-reflective and yellow-transmissive film. It can be understood that in an embodiment, the light guiding element 120 is a prism provided with an optical film, and the prism facilitates multiple reflections of the excitation light in the light source system 100. In other embodiments, the light guiding element 120 can be coated according to the colors of the excitation light and the excited light.
It can be understood that, in an embodiment, the notch 111 can have a shape with which its opening and the bottom wall 111b have different areas. Preferably, an area of the bottom wall 111b is smaller than the area of the opening, such as a circular frustum shape, a circular cone shape, a pyramid shape, or other irregular shapes such as a shape having a U-shaped or V-shaped cross-section,, in order to ensure that the unconverted part of the excitation light emitted from the wavelength conversion layer 150 is incident to the light guiding element 120, then the excitation light is reflected, and it is reflected by the reflective layer 160 to the wavelength conversion layer 150 and converted into excited light, which is then emitted from the light guiding element 120, so that it is also ensured that the excitation light that is not irradiated to the wavelength conversion layer 150 is guided to the wavelength conversion layer 150 through the reflective layer 160 and the light guiding element 120 to be converted into excited light, which is finally emitted from the light guiding element 120. The laser 130 can be disposed on any sidewall of the notch 111. In some possible implementations, the wavelength conversion layer 150 is disposed on the bottom wall of the U-shaped notch; or the wavelength conversion layer 150 is disposed on one sidewall of the V-shaped notch, and the wavelength conversion layer 150 and the laser 130 can be located on a same sidewall or opposite sidewalls.
Referring to FIG. 4 to FIG. 6, FIG. 4 is a cross-sectional view of a light source system 200 provided by a second embodiment of the present disclosure, FIG. 5 is a top view of the light source system 200 shown in FIG. 4, and FIG. 6 is a schematic diagram of spots on a wavelength conversion layer 250 shown in FIG. 4.
The cross-sectional view of the light source system 200 provided in the embodiment as shown in FIG. 4 is obtained in the same manner as the light source system 100.
A difference between the light source system 200 and the light source system 100 mainly lies in: the laser 230 in the light source system 200 is received in the sidewall 211a of the notch 211 of the substrate 210 at a preset angle, in such a manner that the excitation light emitted by the laser 230 propagates along a straight line to be irradiated to the wavelength conversion layer 250, and the beam deflecting device is omitted. It should be noted that, within the scope of the spirit or basic features of the present disclosure, various specific solutions applicable to the first embodiment can also be correspondingly applied to the second embodiment and will not be repeated herein to save space and avoid duplication.
Specifically, as shown in FIG. 4 and FIG. 5, the laser 230 is at a certain angle with respect to the bottom wall 211b in a perpendicular direction, in such a manner that the excitation light emitted by the laser 230 propagates along a straight line to be irradiated to the wavelength conversion layer 250, thereby omitting the beam deflecting device; as shown in FIG. 5, the laser 230 is at a certain angle with respect to the sidewall 211a in a horizontal direction, in such a manner that spots formed on the wavelength conversion layer 250 by any two lasers 130 partially overlap and partially do not overlap, and then spots emitted by the lasers 230 can be more uniformly irradiated on the wavelength conversion layer 250, which can avoid a problem that a conversion efficiency of the wavelength conversion layer 250 is reduced due to excessive local heat of the wavelength conversion layer 250. The laser spots irradiated on the wavelength conversion layer 250 are as shown in FIG. 6.
The light source system 200 provided in the second embodiment can solve the heat dissipation problems of the laser 230 and the wavelength conversion layer 250, and the light source system 200 and a lighting device to which the light source system 200 is applied have a small volume and a simple and compact structure. In addition, the number of optical devices used in the light source system 200 is reduced, an internal space of the light source system 200 is saved, and the cost is lower.
Referring to FIG. 7, which is a cross-sectional view of a light source system 100 provided by a third embodiment of the present disclosure as shown in FIG. 1.
The cross-sectional view of the light source system 300 provided in the embodiment as shown in FIG. 7 is obtained in the same manner as the light source system 100.
A difference between the light source system 300 and the light source system 100 mainly lies in: the laser 330 of the light source system 300 emits excitation light in a first polarization state, the wavelength conversion layer 350 changes a polarization state of the excitation light, the light guiding element 320 is a polarizing prism plated with an optical film, the polarizing prism is configured to reflect light of the first polarization state and transmit light of another polarization state, that is, the polarization state of the excitation light of the first polarization state is changed by the wavelength conversion layer 350, and the excitation light of the first polarization state is finally emitted from the light guiding element 320 in forms of other polarization states, excited light of other polarization states is also emitted from the light guiding element 320, and blue excitation light and yellow excited light that are emitted from the light guiding element 320 are combined to obtain white light source light. It should be noted that, within the scope of the spirit or basic features of the present disclosure, various specific solutions applicable to the first embodiment can also be correspondingly applied to the second embodiment and will not be repeated herein in order to save space and avoid duplication.
The light source system 300 provided in the third embodiment can solve the heat dissipation problems of the laser 330 and the wavelength conversion layer 350 of the light source system 300, and the light source system 300 and a lighting device to which the light source system 300 is applied have a small volume and a simple and compact structure.
The above are only the embodiments of the present disclosure and do not limit the patent scope of the present disclosure. Any equivalent structure or equivalent process transformation made by using the description and drawings of the present disclosure, or those directly or indirectly used in other related technical fields are similarly included in the patent protection scope of the present disclosure.

Claims

A light source system, comprising:
at least one laser configured to emit excitation light;

a substrate made of material with a high thermal conductivity, wherein the substrate is provided with a notch, and the at least one laser is received in a sidewall of the notch;

a reflective layer covering a wall of the notch and configured to reflect the excitation light;

a wavelength conversion layer provided on a part of a surface of the reflective layer and configured to perform wavelength conversion on the excitation light to obtain excited light; and

a light guiding element covering an opening of the notch and configured to guide the excitation light and the excited light, to obtain light source light to be emitted by the light source system.
The light source system according to claim 1, wherein the light guiding element comprises a beam-splitting filter.
The light source system according to claim 1, wherein the notch comprises a bottom wall and the sidewall, and the bottom wall has an area different from the opening.
The light source system according to claim 3, wherein the reflective layer covers both the bottom wall and the sidewall of the notch, and the wavelength conversion layer is disposed on a surface of the reflective layer covering the bottom wall.
The light source system according to claim 4, further comprising:
at least one beam deflecting device in one-to-one correspondence with the at least one laser, wherein each of the at least one beam deflecting device is configured to guide excitation light emitted by corresponding one of the at least one laser to irradiate the wavelength conversion layer.
The light source system according to claim 5, wherein the notch has a shape of a frustum, the at least one laser is exposed out of a surface of the substrate, any two lasers of the at least one laser are received in different sidewalls of the notch, and each of the at least one beam deflecting device is disposed between the corresponding one of the at least one laser and the light guiding element.
The light source system according to claim 4, wherein each of the plurality of lasers is received in the sidewall of the notch at a preset angle, in such a manner that excitation light emitted by the laser propagates in a straight line to irradiate the wavelength conversion layer.
The light source system according to claim 6, wherein spots formed on the wavelength conversion layer by any two of the at least one laser partially overlap.
The light source system according to claim 1, wherein the light guiding element is a prism.
The light source system according to claim 8, wherein the at least one laser emits excitation light in a first polarization state, the wavelength conversion layer is configured to change the polarization state of the excitation light, and the prism is configured to reflect light of the first polarization state and transmit light of another polarization state.
A lighting device, comprising the light source system according to any one of claims 1-10.